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CN103199343B - Patch antenna device and antenna assembly - Google Patents

Patch antenna device and antenna assembly Download PDF

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Publication number
CN103199343B
CN103199343B CN201310061377.3A CN201310061377A CN103199343B CN 103199343 B CN103199343 B CN 103199343B CN 201310061377 A CN201310061377 A CN 201310061377A CN 103199343 B CN103199343 B CN 103199343B
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CN
China
Prior art keywords
patch antenna
antenna element
electrode
patch
gain
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Fee Related
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CN201310061377.3A
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Chinese (zh)
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CN103199343A (en
Inventor
柴田治
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Murata Manufacturing Co Ltd
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Murata Manufacturing Co Ltd
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Filing date
Publication date
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Publication of CN103199343A publication Critical patent/CN103199343A/en
Application granted granted Critical
Publication of CN103199343B publication Critical patent/CN103199343B/en
Expired - Fee Related legal-status Critical Current
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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/0407Substantially flat resonant element parallel to ground plane, e.g. patch antenna
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q21/00Antenna arrays or systems
    • H01Q21/06Arrays of individually energised antenna units similarly polarised and spaced apart
    • H01Q21/08Arrays of individually energised antenna units similarly polarised and spaced apart the units being spaced along or adjacent to a rectilinear path
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/0407Substantially flat resonant element parallel to ground plane, e.g. patch antenna
    • H01Q9/0414Substantially flat resonant element parallel to ground plane, e.g. patch antenna in a stacked or folded configuration

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  • Waveguide Aerials (AREA)
  • Variable-Direction Aerials And Aerial Arrays (AREA)
  • Details Of Aerials (AREA)

Abstract

The present invention provides a kind of deterioration avoiding the radioactive nature such as gain or efficiency, and seeks patch antenna device and the antenna assembly of miniaturization.Upper formation the 1st electrode (3) in the front (2a) of rectangular-shaped dielectric base body (2), and upper the 2nd electrode (4) that formed in the back side (2b) in dielectric base body (2), and by coaxial cable (120), the 1st electrode (3) is connected on power supply section (100).And, the width (W) of the 1st and the 2nd electrode (3,4) is set as less than 1/4th of its length (L), and the thickness (T) of dielectric base body (2) is set as more than one times of described width (W).More preferably the 2nd electrode (4) is set to longer than the 1st electrode (3), and is arranged in the both ends of the surface (2e, 2f) of dielectric base body (2) after the both ends bending of the 2nd electrode (4).

Description

Patch antenna device and antenna assembly
The application is filing date on 08 22nd, 2007 (enter State Period date be on May 6th, 2009), application number Be 200780041230.0, the divisional application of the application for a patent for invention of invention entitled " patch antenna device and antenna assembly ".
Technical field
The present invention relates to a kind of patch antenna device that can be used for UHF band RFID handheld terminal etc. and antenna assembly.
Background technology
Patch antenna device is made up of following components: the ground electrode formed by conductor, is loaded in this ground electrode On dielectric base body, the radiation electrode of the conductor being formed in this dielectric base body.
The patch antenna device of this structure has and can not only realize slimming and can obtain high-gain, and and coaxial line Compatibility between the unbalanced circuits such as road or micro-strip (micro strip) circuit is good, can match these circuit easily Medium lot of advantages.
Therefore, (for example, referring to patent literary composition during patch antenna device is widely used in RFID handheld terminal or other transceiver Offer 1).
Patch antenna device is utilized as patch antenna element it addition, have also been devised in antenna assembly, and by these The array type antenna assembly (for example, referring to patent documentation 2) that multiple patch antenna element arrange and constitute.
This array type antenna assembly typically uses planar structure.That is, plane row on the wide surface of a piece of dielectric base body Arrange multiple radiation electrode, and lateral each radiation electrode connecting coaxial cable from the back side of dielectric base body, by this coaxial cable There is provided from the power of power supply section to each radiation electrode, or strip line (strip is set on the back side of dielectric base body etc. Line), it is electromagnetically coupled to each radiation electrode by the power in self-powered in future portion through this strip line, makes the electricity from radiation electrode Ripple emits to the vertical frontal that dielectric base body surface is corresponding.
Patent documentation 1: JP 2006-245751 publication
Patent documentation 2: JP 2001-111336 publication
But, there is problems with in described conventional patch antenna device.
When miniaturized patch antenna device, the method taking to improve the relative dielectric constant of dielectric base body.But, carry The relative dielectric constant of high dielectric matrix, thus while reducing antenna electrode size, if the chi of ground electrode to be reduced Very little, then can increase the radiation to back-side ground side, and the radiation gain to face side can be reduced.
That is, if miniaturized patch antenna device, then deterioration F/B ratio (Front to Back ratio) drastically can be produced Reduce the defect of the gain of frontal.
Therefore, in the patch antenna device using high-k matrix, to obtain desired gain or F/B ratio, Then have to be dimensioned so as to ground connection more than half-wavelength level, be otherwise difficulty with the miniaturization of patch antenna device.
As it has been described above, in the conventional patch antenna device utilizing paster antenna, it is impossible to obtain gain or F/B ratio simultaneously The miniaturization of increase and device.
It addition, in conventional array type patch antenna device, owing to using on the wide surface of a piece of dielectric base body Arrange the planar structure of multiple radiation electrode, in miniaturized electronics, therefore need wide erection space, and in narrow sky Cannot install in line installation region.To this, it is also recognized that reduce the method that antenna element number of packages realizes miniaturization, but if reduce Antenna element number of packages, can cannot obtain desired gain.
Summary of the invention
The present invention makes to solve described problem, it is therefore an objective to provide a kind of guarantee to frontal enough While gain, miniaturization can be realized and patch antenna device and the antenna assembly of directivity can be changed easily.
In order to solve described problem, invention 1 is a kind of patch antenna device with following components: front and the back side Opposite one another, and the section vertical with these front and backs is generally rectangular the dielectric base body of shape;It is formed at this electricity to be situated between The front of matter matrix, and it is connected to the 1st electrode of power supply section;With the 2nd electrode at the back side being formed at this dielectric base body, its structure Become: the width setup of the 1st electrode is less than 1/4th of the 1st electrode length towards excitation orientation, and the width of the 2nd electrode Spend and be set as less than 1/4th of the 2nd electrode length towards excitation orientation, and the front and back of dielectric base body Respective width setup is the respective width equal to the 1st and the 2nd electrode, and the thickness of this dielectric base body is set as this width More than one times.
According to this structure, from power supply section to 1 electrode power supply time, from the electromagnetic wave of the 1st electrode radiation assigned frequency.This Time, owing to the width of the 1st electrode and the 2nd electrode is respectively set to less than 1/4th of its length, and, dielectric base body The width of front and back is also set to, equal to these the 1st electrode and the respective width of the 2nd electrode, therefore, seek paster The miniaturization that antenna assembly is overall, but there is the hidden danger of the gain reduction of patch antenna device.But, in the paster sky of this invention In line apparatus, the thickness of dielectric base body is set as more than a times of this width, therefore inhibits the reduction of gain, it can be ensured that Enough gains.
The composition of invention 2 is: in the patch antenna device described in invention 1, the length of at least one of the 1st or the 2nd electrode Degree is set to longer than the length in the front of dielectric base body or the back side, and bends the both ends of this length direction, is arranged in this electricity The both ends of the surface of dielectric matrix.
The composition of invention 3 is: in the patch antenna device described in invention 1 or invention 2, the length of the 2nd electrode is set to Longer than the length of the 1st electrode.
The composition of antenna assembly of invention 4 is: be respectively provided with the most opposed almost parallel in dielectric base body of electrode Two faces on and a pair patch antenna element being formed the most arranged in parallel be the electrode of a patch antenna element The mode facing with the electrode of another patch antenna element, powers and as power supply component to a patch antenna element, And using another patch antenna element as unpowered element.
According to this structure, when a patch antenna element as power supply component is powered, radiate from patch antenna element The electromagnetic wave of assigned frequency.Then, with another patch antenna element electromagnetic coupled, make another patch antenna element with these rule Determine frequency and produce resonance.
Now, by between the suitable reactance value setting another patch antenna element self or a pair patch antenna element Every, it is possible to make the electromagnetic wave radiated from another patch antenna element and from a patch antenna element towards another paster antenna The electromagnetic wave of element produces interference.
Specifically, by suitably setting reactance value, change the electromagnetic wave that radiates from another patch antenna element Phase place or amplitude, and the interval of a pair patch antenna element is set by corresponding wavelength, it is possible to increase from a paster antenna The gain of the electromagnetic wave that element radiates to frontal, and can decay and be present in the electromagnetic wave in direction, the back side, and F/B can be improved Ratio.
The composition of invention 5 is: in the antenna assembly described in invention 4, described in any one of utilization invention 1 to invention 3 Patch antenna device is as patch antenna element.
The composition of invention 6 is: in the antenna assembly described in invention 4 or invention 5, as the paster antenna of unpowered element Element arrangements is in the position with the radiation direction opposite side of the patch antenna element as power supply component.
The composition of invention 7 is: in the antenna assembly described in any one of invention 4 to invention 6, as unpowered element Connect reactance circuit in patch antenna element and be used as terminal.
According to this structure, by the electricity of the reactance circuit that change is connected in the patch antenna element as unpowered element Anti-value, it is not necessary to improve the reactance value of patch antenna element self, it becomes possible to improve the reactance value of unpowered component side.
The composition of invention 8 is: in the antenna assembly described in any one of invention 4 to invention 7, a pair patch antenna element Interval be set as using more than 0.12 times and less than 0.30 times of free space wavelength of frequency.
According to this structure, optimal gain and F/B ratio can be obtained.
The composition of invention 9 is: a pair patch antenna element described in any one of utilization invention 4 to invention 8 is as submatrix Column unit, is positioned at the behind of the unpowered element of previous sub-array units according to the power supply component of later sub-array units Multiple sub-array units are formed a line by mode at regular intervals, and wherein, one patch antenna element is as the 1st paster Antenna element, and another patch antenna element described is as the 2nd patch antenna element, and by each patch antenna element One electrode is as the 1st electrode, and using another electrode as the 2nd electrode, and according to the 2nd patch of previous sub-array units The mode of the 1st electrode contraposition of the 2nd electrode of chip antenna element and the 1st patch antenna element of later sub-array units, will The plurality of sub-array units is arranged in string at regular intervals.
According to this structure, due to the 1st patch antenna element as previous power supply component and as later unpowered 2nd patch antenna element of element is the most alternately arranged, therefore the 1st patch antenna element and the 2nd patch antenna element Along the radiation direction of electric wave in the state being arranged in string.Therefore, in the antenna assembly of this invention, and in dielectric base body On surface, the conventional array type patch antenna device of the multiple radiation electrode of planar alignment is different, even for without surface direction Broadening and the narrow electronic equipment of antenna erection space also can be installed easily.
It addition, in each sub-array units, when the 1st patch antenna element is powered, from the 1st patch antenna element forwards and The electric wave of rear radiation assigned frequency.And, rearward electric wave and the 2nd patch antenna element electromagnetic coupled, therefore the 2nd paster Antenna element produces resonance with this assigned frequency.Now, by suitably setting the reactance of the 1st and the 2nd patch antenna element self Value or the element spacing of these elements, enabling rearward electric wave of decaying, and it is only capable of improving the gain of electric wave forwards. According to this setting, each sub-array units can forwards radiate the electric wave of high-gain.Therefore, in the antenna assembly of this invention, by In such multiple sub-array units according to the 2nd electrode and later of the 2nd patch antenna element of previous sub-array units The mode of the 1st electrode contraposition of the 1st patch antenna element of sub-array units is arranged in string at predetermined intervals, therefore, passes through Suitably set each sub-array units interval each other, make the electric wave forwards radiated from each sub-array units the most overlapping, It is thus possible to increase the gain of the electric wave from antenna assembly radiation.That is, can increase traditional thread binding from sky according to the quantity of sub-array units Put the gain of the electric wave penetrated.
The composition of invention 10 is: in the antenna assembly described in invention 9, previous sub-array units and later subarray The predetermined distance of unit is set as using 1st/2 of the free space wavelength of frequency, to later sub-array units The power supply of the 1st patch antenna element arranges substantially 180 ° with the power supply of the 1st patch antenna element to previous sub-array units Phase contrast.
According to this structure, from electric wave and the electric wave from the radiation of later sub-array units of previous sub-array element radiation Unanimously, the gain of the electric wave radiated from antenna assembly can actually be improved.
The composition of invention 11 is: in the antenna assembly described in invention 9 or invention 10, the 2nd paster of each sub-array units Reactance circuit it is connected on antenna element.
According to this structure, it is connected to the reactance value of the reactance circuit of the 2nd patch antenna element by change, it is not necessary to improve the The reactance value of 2 patch antenna element self, it becomes possible to improve the reactance value of the 2nd patch antenna element.
The composition of antenna assembly of invention 12 is: be respectively provided with the most opposed almost parallel in dielectric base body of electrode Two faces on and a pair patch antenna element being formed the most arranged in parallel be the electrode of a patch antenna element The mode facing with the electrode of another patch antenna element, and power respectively as confession to the pair of patch antenna element Electric device.
According to this structure, when a pair patch antenna element as power supply component is powered respectively, respectively from paster antenna The electromagnetic wave of two electrode radiation assigned frequencies of element.Now, radiated from another patch antenna element by suitably setting The phase place of electromagnetic wave or amplitude, it is possible to make the electromagnetic wave radiated from another patch antenna element with from a paster antenna unit The electromagnetic wave that part radiates towards another patch antenna element produces interference.That is, by suitably setting from another paster antenna unit The phase place of the electromagnetic wave of part radiation or amplitude, can make the gain of the electromagnetic wave radiated from a patch antenna element to frontal Improve, and can decay and be present in the electromagnetic wave in direction, the back side, and F/B ratio can be improved.
The composition of invention 13 is: in the antenna assembly described in invention 12, described in any one of utilization invention 1 to invention 3 Patch antenna device as patch antenna element.
The composition of invention 14 is: in the antenna assembly described in invention 12 or invention 13, supply to a patch antenna element The signal of electricity is set as more than 60 degree and less than 120 degree with the phase contrast of the signal powered to another patch antenna element.
The composition of invention 15 is: in the antenna assembly described in any one of invention 12 to invention 14, from a paster Antenna element radiation electric wave amplitude be set as than from another patch antenna element radiation electric wave the high 2dB of amplitude with Go up and below 6dB.
The composition of invention 16 is: be positioned at the side of the behind of previous patch antenna element according to later patch antenna element Multiple patch antenna element are formed a line by formula at regular intervals, and power respectively to each patch antenna element, wherein, and each paster 1st and the 2nd electrode of antenna element is separately positioned on the front and back of dielectric base body, according to previous patch antenna element The mode of the 1st electrode contraposition of the 2nd electrode and later patch antenna element, by multiple patch antenna element at regular intervals It is arranged in string.
According to this structure, due to according to the 2nd electrode of previous patch antenna element and later patch antenna element The mode of the 1st electrode contraposition arranges multiple patch antenna element, the most multiple patch antenna element along electric wave radiation direction in It is arranged in the state of string.Therefore, in the antenna assembly of this invention, multiple with planar alignment on the surface of dielectric base body The conventional antenna assembly of radiation electrode is different, even for the electronics narrow without the broadening of surface direction and antenna erection space Equipment also can be installed easily.
It addition, when each patch antenna element is powered, from the electric wave of patch antenna element radiation assigned frequency.Therefore, exist In the antenna assembly of this invention, owing to such multiple patch antenna element are according to the 2nd electrode of previous patch antenna element Arrange at predetermined intervals with the mode of the 1st electrode contraposition of later patch antenna element, therefore by suitably setting paster sky Kind of thread elements each other be interval in each patch antenna element phase place, the electric wave radiated from each patch antenna element can be made to weigh each other Folded, it is thus possible to increase the gain of the electric wave from antenna assembly radiation.That is, can increase from antenna according to the quantity of patch antenna element The gain of the electric wave of device radiation.
The composition of invention 17 is: in the antenna assembly described in invention 16, and previous patch antenna element is pasted with later The predetermined distance of chip antenna element is set as using 1st/4 of the free space wavelength of frequency, to later paster sky The power supply of kind of thread elements and the phase contrast arranging substantially 90 ° that previous patch antenna element is powered.
According to this structure, the electric wave radiated from previous patch antenna element with from the radiation of later patch antenna element Electric wave is consistent, can actually improve the gain of the electric wave radiated from antenna assembly.
The composition of invention 18 is: in the antenna assembly described in invention 16 or invention 17, utilizes invention 1 appointing to invention 3 One described patch antenna device is as patch antenna element.
The composition of antenna assembly of invention 19 is: be respectively provided with the most opposed almost parallel in dielectric base body of electrode Two faces on and a pair patch antenna element being formed the most arranged in parallel be the electrode of a patch antenna element The mode facing with the electrode of another patch antenna element, and a pair drawn respectively from the pair of patch antenna element Supply lines is connected to power supply section by switching switch.
According to this structure, switching switching switchs, when the state that a patch antenna element is connected with power supply section, and this Patch antenna element becomes power supply component, and another patch antenna element becomes unpowered element.Its result, from a paster sky The electromagnetic wave of kind of thread elements radiation assigned frequency.Then, with another patch antenna element electromagnetic coupled, another paster antenna is made Element is with this assigned frequency resonance.Now, by suitably setting the reactance value or of the supply lines of another patch antenna element Interval to patch antenna element, it is possible to make the electromagnetic wave radiated from another patch antenna element and from a paster antenna unit The electromagnetic wave that part radiates towards another patch antenna element produces interference.Specifically, by suitably set supply lines length Degree, changes phase place or the amplitude of the electromagnetic wave radiated from another patch antenna element, and corresponding wavelength sets a pair patch The interval of chip antenna element, it is possible to increase from the gain of the electromagnetic wave that a patch antenna element is radiated to frontal, and Can decay and be present in the electromagnetic wave in direction, the back side, improve F/B ratio.I.e., in this condition, a patch antenna element just The electromagnetic wave of high-gain is radiated on direction, face.Here, switching switching switch again, at another patch antenna element and power supply section During the state connected, this another patch antenna element becomes power supply component, and a patch antenna element becomes unpowered element. Its result, becomes the electric wave from the direction, the back side of another patch antenna element radiation high-gain.That is, from the front of antenna assembly The switching that the electromagnetic wave of direction radiation is switched by switching, becomes and emits to direction, the back side.
The composition of invention 20 is: be respectively provided with electrode on the most opposed almost parallel two face of dielectric base body And formed three patch antenna element electrodes for adjacent patch antenna element the most arranged in parallel are practised physiognomy each other To mode, power as power supply component to middle patch antenna element, and connect in other patch antenna element can Power transformation reactive circuit is used as unpowered element.
According to this structure, when the patch antenna element of the centre as power supply component is powered, put from patch antenna element Penetrate the electric wave of assigned frequency.And, the electromagnetic wave radiated to both sides from this patch antenna element and the patch antenna element of both sides Electromagnetic coupled, makes the patch antenna element of both sides with this assigned frequency resonance.Now, suitably set between patch antenna element Every, and utilize and can change reactance value by reactance circuit, make of patch antenna element of the both sides as unpowered element be Capacitive character, and when another is Irritability, Irritability patch antenna element just plays the effect such as reflector.Therefore, from The electromagnetic wave that middle patch antenna element is radiated to Irritability patch antenna element side is complete in Irritability patch antenna element Return is reflected in portion, produces interference with the electromagnetic wave emitting to capacitive character patch antenna element side and is exaggerated.Its result, therefrom Between patch antenna element to capacitive character patch antenna element direction radiation high-gain and the electromagnetic wave of high F/B ratio.It addition, utilize Reactance value can be changed by reactance circuit, when making the capacitive character of the patch antenna element of both sides and Irritability contrary, from middle paster The direction of the electromagnetic wave of antenna element radiation also can be contrary.
The composition of invention 21 is: in the antenna assembly described in invention 19 or invention 20, utilizes invention 1 appointing to invention 3 One described patch antenna device is as patch antenna element.
The composition of invention 22 is: in the antenna assembly described in invention 20 or invention 21, utilizing varactor to be formed can Power transformation reactive circuit.
The composition of invention 23 is: in the antenna assembly described in invention 20 or invention 21, variable reactance circuit utilizes switch Multiple constant reactance circuit that switching reactance value is different.
As mentioned details, for the patch antenna device of invention 1, due to the width setup of the 1st and the 2nd electrode For less than 1/4th of length, and the width of width setup Cheng Yu the 1 and the 2nd electrode of dielectric base body is equal, therefore can Enough seek the miniaturization that patch antenna device is overall.And, the thickness of dielectric base body is set as more than one times of this width, Suppress the decline of electromagnetic wave gain, therefore, it is possible to guarantee enough gains.That is, for this invention, have and be able to ensure that The prominent effect of the miniaturization of device can be sought while desired gain.Therefore, even if by its volume size miniaturization Also identical gain can be obtained to about the 1/2 of conventional patch antenna device.
For invention 2, owing to the bending of the both ends of any one of the 1st and the 2nd electrode is arranged in In the both ends of the surface of dielectric base body, therefore can be by patch antenna device miniaturization more further.
It addition, for invention 3, owing to the length of the 2nd electrode is set to longer than the length of the 1st electrode, therefore protect The gain to frontal can be effectively improved while holding the miniaturization of patch antenna device.
For the antenna assembly of invention 4, a pair paster formed by arranging electrode in dielectric base body respectively Antenna element constitutes antenna assembly, according to this structure, it is possible to increase to gain or the F/B ratio of the electromagnetic wave of frontal radiation, Therefore there is the antenna assembly seeking miniaturization while can providing the enough gains guaranteed to frontal or F/B ratio Prominent effect.
It addition, for invention 6, using the teaching of the invention it is possible to provide more seek the antenna assembly of miniaturization and high-gain/high F/B ratio.
For invention 7, owing to unpowered component side inherently can be increased without becoming big patch antenna element Reactance value, therefore the more miniaturization of antenna assembly becomes possibility.
And, according to invention 8, it is possible to obtain the antenna assembly guaranteeing optimal gain with F/B ratio.
For the antenna assembly of invention 9 and invention 16, can realize suppressing the miniaturization of the broadening of surface direction, its knot Really, also can install easily for the electronic equipment that antenna erection space is narrow.And, it is possible to according to the quantity of patch antenna element Increase the gain of the electric wave radiated from antenna assembly.That is, high-gain can be obtained according to the antenna assembly of this invention, and have The prominent effect of miniaturization can be realized.
Further, since using patch antenna element as element, therefore and between the unbalanced circuit such as coaxial line Coupling becomes easy, and also has the effect that can more effectively power to antenna assembly from power supply section.
For invention 10 and invention 17, there is the gain that can actually increase the electric wave from antenna assembly Effect.
It addition, for invention 11, owing to inherently can without becoming the 2nd patch antenna element of big each sub-array units Increasing the reactance value of the 2nd patch antenna element, therefore the more miniaturization of antenna assembly becomes possibility.
For the antenna assembly of invention 12, a pair paster formed by arranging electrode in dielectric base body respectively Antenna element constitutes antenna assembly, and passes through both patch antenna element as power supply component, it is possible to increase to front side To the gain of electric wave or the F/B ratio of radiation, therefore have and the enough gains guaranteed to frontal or F/B ratio can be provided Seek the prominent effect of the antenna assembly of miniaturization simultaneously.
It addition, according to invention 14 and invention 15, it is possible to obtain the antenna assembly guaranteeing optimal gain with F/B ratio.
For the antenna assembly of invention 19, have and utilization switching switch can be provided to change high-gain and height easily The prominent effect of the compact-size antenna device of the directivity of the electric wave of F/B ratio.
It addition, for invention 20 for, have can provide by variable reactance circuit change reactance value change easily The prominent effect of the compact-size antenna device of the directivity of the electric wave of high-gain and high F/B ratio.
Accompanying drawing explanation
Fig. 1 is the axonometric chart of the patch antenna device of the 1st embodiment representing this invention.
Fig. 2 is the profilograph of the patch antenna device of Fig. 1.
Fig. 3 is the drawing in side sectional elevation of the patch antenna device of Fig. 1.
Fig. 4 is the expanded view of the patch antenna device of Fig. 1.
Fig. 5 is the axonometric chart of the patch antenna device representing existing type.
Fig. 6 is the front view of patch antenna device and its CURRENT DISTRIBUTION schematically illustrating existing type.
Fig. 7 is the axonometric chart for the relation between the width of electrode and the thickness of dielectric base body is described.
Fig. 8 is the chart representing the relation between the width of patch antenna device and thickness and gain.
Fig. 9 is the chart representing the relation between the width of patch antenna device and thickness and efficiency.
Figure 10 is for the effect represented by the patch antenna device of this embodiment and the profile of effect are described.
Figure 11 is the axonometric chart of the patch antenna device of the 2nd embodiment representing this invention.
Figure 12 is the axonometric chart representing the 2nd electrode length variable condition.
Figure 13 is the chart representing the dependency relation between the length of the 2nd electrode and gain, F/B ratio, frequency band.
Figure 14 is the schematic isometric of the patch antenna device of the 3rd embodiment representing this invention.
Figure 15 is the expanded view of patch antenna element.
Figure 16 is the constructed profile of the patch antenna element as power supply component.
Figure 17 is the schematic isometric of the patch antenna element as unpowered element.
Figure 18 is for the effect represented by the antenna assembly of the 3rd embodiment and the diagrammatic side view of effect are described.
Figure 19 is the relevant figure between element spacing to gain.
Figure 20 is the relevant figure between element spacing to F/B ratio.
Figure 21 is the relevant figure between reactance value, element spacing and gain.
Figure 22 is the relevant figure between reactance value, element spacing and F/B ratio.
Figure 23 is the schematic diagram of the structure of the antenna assembly of the 4th embodiment representing this invention.
Figure 24 is the axonometric chart representing each sub-array units structure.
Figure 25 is the constructed profile of the 1st patch antenna element.
Figure 26 is the side view of the 2nd patch antenna element.
Figure 27 is the side view of the 2nd patch antenna element representing reactance circuit variation.
Figure 28 is for the diagrammatic side view that the electric wave of each sub-array units radiates is described.
Figure 29 is for the effect represented by antenna assembly and the schematic diagram of effect are described.
Figure 30 is the relevant figure between the parts number of patch antenna element and gain.
Figure 31 is the schematic isometric of the antenna assembly of the 5th embodiment representing this invention.
Figure 32 is the constructed profile of each patch antenna element.
Figure 33 is for the effect represented by the antenna assembly of the 5th embodiment and the diagrammatic side view of effect are described.
Figure 34 is the relevant figure between phase contrast, amplitude ratio and gain.
Figure 35 is the relevant figure between phase contrast, amplitude ratio and F/B ratio.
Figure 36 is the schematic diagram of the antenna device arrangement of the 6th embodiment representing this invention.
Figure 37 is the axonometric chart representing antenna device arrangement.
Figure 38 is the schematic diagram for antenna assembly role and effect are described.
Figure 39 is the relevant figure between parts number to gain.
Figure 40 is the schematic isometric of the antenna assembly of the 7th embodiment representing this invention.
Figure 41 is the constructed profile representing the connection status between each patch antenna element, switching switch, power supply section.
Figure 42 is for the antenna assembly role of the 7th embodiment and the diagrammatic side view of effect are described.
Figure 43 is to represent the patch antenna element in left side as the diagrammatic side view of directivity during power supply component.
Figure 44 is to represent the patch antenna element on right side as the diagrammatic side view of directivity during power supply component.
Figure 45 is the diagrammatic side view of the relative status of a pair patch antenna element being denoted as power supply component.
Figure 46 is the schematic isometric of the antenna assembly of the 8th embodiment representing this invention.
Figure 47 is the patch antenna element constructed profile being denoted as unpowered element.
Figure 48 is for the antenna assembly role of the 8th embodiment and the diagrammatic side view of effect are described.
Figure 49 is the diagrammatic side view of the directivity representing antenna assembly.
Figure 50 is the profile of the major part of the antenna assembly of the 9th embodiment representing this invention.
Figure 51 is the axonometric chart of the 1st variation representing described embodiment.
Figure 52 is the axonometric chart of the 2nd variation representing described embodiment.
Figure 53 is the axonometric chart of the 3rd variation representing described embodiment.
Figure 54 is the axonometric chart of the 4th variation representing described embodiment.
Figure 55 is the diagrammatic side view of the 5th variation representing described embodiment.
In figure: 1-patch antenna device;1A, 1B-patch antenna element;2,2A, 2B-dielectric base body;2a、2Aa、2Ba- Front;2b, 2Ab, 2Bb-back side;2c, 2d, 2Ac, 2Ad, 2Bc, 2Bd-side;2e, 2f, 2Ae, 2Af, 2Be, 2Bf-end face; 2g, 4a, 2Ag, 4Aa, 2Bg, 4Ba-hole;2h-space;3,4,3A, 4A, 3B, 4B-electrode;5-reactance circuit;6-allotter;31、 32-bending section;33,43,51,52-lead division;41,42-both ends;53-varicap;54-inductance;55-switching is opened Close;56~59-constant reactance circuit;61-travelling contact;62,63-fixed contact;100-power supply section;110,120-coaxial electrical Cable;111,121-inner conductor;122-external conductor;130,131,140,141-wire;200~205-antenna assemblies;210-1 ~210-n-sub-array units;D, D1-are spaced;L-length;T-thickness;U1~Un, V2, V3-electric wave;W-width;W0, W1~ Wn-power.
Detailed description of the invention
Embodiment hereinafter, with reference to the accompanying drawings of this invention.
(embodiment 1)
Fig. 1 is the axonometric chart of the patch antenna device of the 1st embodiment representing this invention, and Fig. 2 is the paster antenna dress of Fig. 1 The profilograph put, Fig. 3 is the drawing in side sectional elevation of the patch antenna device of Fig. 1, and Fig. 4 is the expanded view of the patch antenna device of Fig. 1.
As it is shown in figure 1, the patch antenna device 1 of this embodiment has dielectric base body the 2, the 1st electrode the 3, the 2nd electrode 4.
Dielectric base body 2 is in rectangular-shaped.Specifically, as in figure 2 it is shown, the front 2a and back side 2b of dielectric base body 2 It is opposite, as it is shown on figure 3, the section vertical with front 2a and back side 2b is rectangle.That is, side 2c, 2d of dielectric base body 2 Intermediate drum as shown by dashed lines does not gets up, but in linearity as shown by the solid line.
As shown in Figure 4, the 1st and the 2nd electrode 3,4 be separately positioned on the front 2a of dielectric base body 2, whole of back side 2b On.I.e., in this embodiment, by the width setup of the front 2a of dielectric base body 2, back side 2b be equal to the 1st and the 2nd electrode 3, The width W of 4.And, in this embodiment, the thickness T of dielectric base body 2 is set as the width W's of the 1st and the 2nd electrode 3,4 More than 1 times so that dielectric base body 2 has certain thickness.
In Fig. 1, the 1st electrode 3 is the radiation electrode that pattern is formed on the front 2a of dielectric base body 2, by as confession The coaxial cable 120 of electric wire is connected on power supply section 100, and its length direction (above-below direction in Fig. 1) is as excitation orientation.
Specifically, as in figure 2 it is shown, hole 2g, the 4a to the 1st electrode 3 to be opened in respectively dielectric base body the 2, the 2nd electrode 4 On, and the inner conductor 121 of coaxial cable 120 is inserted in this some holes 2g, 4a so that it is it is connected on the 1st electrode 3, thus The 1st electrode 3 is made to be electrically connected on power supply section 100.It addition, the external conductor 122 of coaxial cable 120 is connected on the 2nd electrode 4.
The width W of the 1st electrode 3 is set as less than 1/4th of length L of the 1st electrode 3 towards excitation orientation.
In Fig. 1, the 2nd electrode 4 is the unpowered electrode that pattern is formed on the back side 2b of dielectric base body 2, with the 1st electrode As 3, the width W of the 2nd electrode 4 is also set to less than 1/4th of length L of the 2nd electrode 4.
That is, the patch antenna device 1 of this embodiment is formed as elongated rectangular-shaped, and is formed as the pros than existing type The device that shape patch antenna device is more small-sized.
Hereinafter, the establishing method of the miniaturization to this patch antenna device 1 is illustrated.
Fig. 5 is the axonometric chart of the patch antenna device representing existing type, and Fig. 6 is the paster antenna dress schematically illustrating existing type Put the front view with its CURRENT DISTRIBUTION.
As it is shown in figure 5, in conventional patch antenna device 1 ', be formed as in the front of dielectric base body 2 ' configuration pros 1st electrode 3 ' of shape, and in the structure of the inside of dielectric base body 2 ' configuration the 2nd electrode 4 ', and by from power supply section 100 The power of assigned frequency is provided to the 1st electrode 3 ', thus to the electric wave of face side radiation regulation resonant frequency.
But, in such patch antenna device 1 ', such as, width W and length L of the 1st electrode 3 ' are all set as Same length, therefore occupied area is big.And, as shown in Figure 6, the current convergence during excitation of the 1st electrode 3 ' is with the 1st electricity The region that I near the side 3 ' a side of pole 3 ' represents.That is, representing such as dotted line, electric current flows to the central authorities of the 1st electrode 3 ' hardly B side, portion 3 ', therefore the central part 3 ' b of the 1st electrode 3 ' becomes the idle state being helpless to excitation.
Therefore, inventor has carried out the research eliminating this part of leaving unused, making every effort to the miniaturization of patch antenna device.
Fig. 7 is the axonometric chart for the relation between the width of electrode and the thickness of dielectric base body is described.
As shown in Fig. 7 (a), by making the 1st electrode 3 ' narrow with the width W of the 2nd electrode 4 ', eliminate the electricity shown in Fig. 6 Region 3 ' the b that stream flows through hardly, it is thus possible to accomplish the miniaturization of patch antenna device 1 '.
But, in this patch antenna device 1 ', owing to making the width W of the 2nd electrode 4 ' also narrow, therefore it is distributed in the 1st Electric current I on electrode 3 ' also diminishes, and can reduce the gain to frontal.So, as shown in Fig. 7 (b), by corresponding 1st electricity The width W of pole 3 ', by thickening for the thickness T of dielectric base body 2 ' such that it is able to increases and is distributed in the electric current I on the 1st electrode 3 ', its As a result, it is possible to improve the gain to frontal.
But, if in order to miniaturization makes the width W of electrode 3 ', 4 ' become the least, then have to make electricity to obtain gain The thickness T of dielectric matrix 2 ' is thickening, and result can cause patch antenna device 1 ' in the maximization of thickness direction.Otherwise, if making electricity The thickness T of dielectric matrix 2 ' is the thickest, if it has to increasing the width W of electrode 3 ', 4 ', result can cause patch antenna device 1 ' Maximization at width.
Therefore, which type of inventor for setting width W or the thickness of dielectric base body 2 ' of the 1st electrode 3 ' in the range of Degree T, can make the problem that patch antenna device is less and gain is more than existing type gain of the existing type of its volume ratio, utilizes Following emulation is studied.
Fig. 8 is the chart representing the relation between the width of patch antenna device and thickness and gain, and Fig. 9 is to represent paster The chart of the relation between width and thickness and the efficiency of antenna assembly.
Inventor utilizes relative dielectric constant to be 6.4, dielectric loss (tan δ) is that the electrolyte of 0.002 is as paster antenna The dielectric base body 2 of device 1, sets its length L as 80mm.That is, the 1st and the 2nd electrode 3,4 and the length of dielectric base body 2 is utilized Degree L is the patch antenna device 1 of 80mm, it is provided that frequency is the power of 910MHz.Then, along with changing patch antenna device 1 Width W (the 1st and the 2nd electrode 3,4 and the width of dielectric base body 2) and thickness T (thickness of dielectric base body 2), simulate Each gain of patch antenna device 1, has obtained the result shown in gain curve G1~G4 of Fig. 8.Here, gain curve G1, G2, G3, G4 represent the relation between the width W in each gain of 1dBi, 2dBi, 3dBi, 3.5dBi and thickness T, and region J represents Width W that the patch antenna device of existing type is used and the scope of thickness T, region H represents the paster antenna dress of this embodiment Put used width W and the scope of thickness T.
As shown in the region J of Fig. 8, in the patch antenna device of existing type, if expecting the gain of 3dBi, then must make Width W is about more than 65mm, thickness T is about about 8mm, and its volume is minimum is also about 41.6cc.In contrast, such as region H institute Show, to be set to width W be less than 1/4th of length 80mm, thickness T be more than width W patch antenna device 1 in, right In obtaining the gain of 3dBi, if width W be 20mm, thickness T be about about 20mm, its volume is about about 32cc i.e. Can.That is, in the patch antenna device 1 of a length of 80mm, it is possible to clearly: by set width W as length 1/4th with Under, thickness T be more than width W, while obtaining identical gain, its volume is relative to the volume of the patch antenna device of existing type Also reduce about more than 25%.
Secondly, inventor utilizes to have possessed and has and described identical relative dielectric constant, dielectric loss and the electricity of length The patch antenna device 1 of dielectric matrix the 2 and the 1st and the 2nd electrode 3,4, it is provided that frequency is the power of 910MHz.Then, along with Change width W and thickness T, simulate each efficiency of patch antenna device 1, obtained institute in lower efficiency curve E1~E3 of Fig. 9 The result shown.
Here, between width W and the thickness T during efficiency curve E1, E2, E3 represents each efficiency of 70%, 80%, 90% Relation.
As shown in the region J of Fig. 9, in the patch antenna device of existing type, if expecting the efficiency of 90%, then must make Width W is about more than 70mm, thickness T is about about 10mm, and its volume is minimum is also about 56cc.In contrast, such as region H institute Show, to be set to width W be less than 1/4th of length 80mm, thickness T be more than width W patch antenna device 1 in, right In obtain 90% efficiency, as long as width W be 20mm, thickness T be about about 20mm, its volume maximum the most about 40cc is left Right.That is, in the patch antenna device 1 of a length of 80mm, it is possible to clearly: by set width W as length four/ Less than one, thickness T is more than width W, and while obtaining same efficiency, its volume is relative to the patch antenna device of existing type Volume also reduces about more than 29%.
The result that inventor studies through simulated effect as above, has obtained drawing a conclusion: by setting paster antenna More than thickness T is width W one times of device 1, width W be less than 1/4th of length L so that with 3dBi gain and 90% The patch antenna device of the existing type of efficiency can be realized as the patch antenna device than existing type with identical gain and efficiency Smaller device.
Therefore, in this embodiment, as it has been described above, set the thickness T of the dielectric base body 2 of patch antenna device 1 as the 1st With more than one times of the width W of the 2nd electrode 3,4, set the width W length as the 1st and the 2nd electrode 3,4 of the 1st and the 2nd electrode 3,4 Less than/4th of degree L.
Below, patch antenna device 1 role and the effect of this embodiment will be illustrated.
Figure 10 is for patch antenna device 1 role of this embodiment and the profile of effect are described.
As shown in Figure 10, the power W0 of assigned frequency is provided through coaxial cable 120 to the 1st electrode 3 from power supply section 100 Time, the 1st electrode 3 works as radiation electrode, it addition, be connected on the external conductor 122 of the coaxial cable 120 of ground connection 2nd electrode 4 works as ground electrode.Its result, the electric wave V of assigned frequency energized in the 1st electrode become to Face side (left side of Figure 10) is radiated.
Now, the width W of the 1st and the 2nd electrode 3,4 is respectively set as less than 1/4th of its length L, and electrolyte The width of the front 2a and back side 2b of matrix 2 is also set to the width W equal to these the 1st and the 2nd electrodes 3,4, therefore, seeks The miniaturization of patch antenna device 1 entirety.Therefore, the narrow RFID's of high-density installation electronic unit and antenna mounting region In handheld terminal or other transceiver, it is also possible to this patch antenna device 1 is installed easily.It is additionally, since dielectric base body 2 Thickness T is set as more than a times of the width W of the 1st and the 2nd electrode 3,4, the most there is not the electric wave V from the 1st electrode 3 radiation The reduction of gain.Thus, the electric wave V of abundant gain can be radiated to the frontal of patch antenna device 1.
For the patch antenna device 1 of this embodiment, miniaturization can not only be realized and go back simultaneously The high-gain to frontal can be obtained.
(embodiment 2)
Below, the 2nd embodiment of this invention will be illustrated.
Figure 11 is the axonometric chart of the patch antenna device of the 2nd embodiment representing this invention.
This embodiment difference from described 1st embodiment is: the length of the 1st and the 2nd electrode 3,4 is different.
As shown in figure 11, patch antenna device 1 in this embodiment " in, set the length of the 2nd electrode 4 than the 1st electrode 3 Length (L) long.Specifically, length L of the 1st electrode 3 is identical with described 1st embodiment with width W, but the 2nd electrode 4 Length be set to than 1 embodiment time length long, and set a length of back side 2b than dielectric base body 2 of the 2nd electrode 4 The length (L+L2 × 2) of length L length.Then bend the both ends 41,42 of the 2nd electrode 4, be arranged in the two ends of dielectric base body 2 On face 2e, 2f.
According to this structure, originally need the electrolyte with the length of length (L+L2 × 2) respective amount with the 2nd electrode 4 Matrix, but just can solve by dielectric base body that the original length is L 2, the most only use bending section 41,42 length (L2 × 2) can be realized as the miniaturization of patch antenna device self.
It addition, by the length increasing the 2nd electrode 4 worked as ground electrode, it is possible to reduce from the 1st electrode 3 Electric wave towards rear side (the 2nd electrode 4 side).Therefore, increase F/B ratio while keeping the miniaturization of patch antenna device, its As a result, it is possible to improve the gain to frontal (left direction of the 1st electrode 3).
But, such as this embodiment, design has the patch antenna device 1 of the length of the 1st and the 2nd electrode 3,4 " time, it is necessary to Seek coupling between the load with power supply section 100 side (such as 50 Ω).In the frequency determined, the may coupled with load The length of the 1 and the 2nd electrode 3,4 has a lot, if determining and the length loading the 2nd electrode 4 coupled, the then length of the 1st electrode 3 Also the length of corresponding 2nd electrode 4 and determine.And, in the frequency determined, the length of the 2nd electrode 4 coupled with load is not only It is only the length of the back side 2b of dielectric base body 2, also can reach both ends of the surface 2e, 2f and the length of front 2a.
But, patch antenna device 1 " gain or F/B than and these radioactive natures of frequency band can be with the length of the 2nd electrode 4 Different and different.Therefore seek these gains or F/B than and frequency band etc., a kind of optimal patch antenna device 1 need to be designed ".
Therefore, it is 6.4 that the 1st and the 2nd electrode 3,4 of different length is formed at relative dielectric constant by inventor, and dielectric is damaged Consumption is 0.002, and length L, width W, thickness T are respectively in the dielectric base body 2 of 80mm, 10mm, 30mm.And, by frequency it is The power of 910MHz is supplied to this patch antenna device 1 ", change the length of the 2nd electrode 4, and simulate patch antenna device 1 " gain, F/B when frequency band.
Figure 12 is the axonometric chart representing the 2nd electrode length variable condition, Figure 13 be represent the length of the 2nd electrode and gain, The chart of the dependency relation between F/B ratio, frequency band.
(a), (b), (c) of Figure 12, (d), (e) represent that setting respectively includes the 2nd electrode 4 of bending section 41,42 length Total length L+L2 × 2 are the patch antenna device 1 when 101mm, 108mm, 114mm, 130mm, 140mm ".At this patch antenna device 1 " in, in order to seek to determine under frequency with coupling between load, including bending section 31,32 the 1st electrode 3 total length L+L1 × 2 set according to the elongated of the 2nd electrode 4 and that shorten mode.
The emulation patch antenna device 1 to each length with the 2nd electrode 4 shown in Figure 12 (a)~(e) is " with the 2nd electrode The total length of 4 is the patch antenna device 1 of 104mm, 113mm, 116mm, 120mm " each device provide frequency be the merit of 910MHz Rate, and determine the gain of each length of the 2nd electrode 4, F/B when frequency band.
Result is as shown in the gain curve S1 of Figure 13, and when the total length of the 2nd electrode 4 is near 108mm, gain is maximum.It addition, As F/B is than shown in curve S2, and F/B is to become big near 114mm~130mm than the total length at the 2nd electrode 4.And, such as frequency band curve S3 Shown in, frequency band is elongated and broaden with the total length of the 2nd electrode 4.But, although frequency band is that the 2nd electrode 4 is the longest, become the widest, and In contrast, gain or F/B ratio can reduce, and additionally also become increasingly difficult to, therefore by the length of the 2nd electrode 4 with 50 coupling of Ω load Degree is set as that more than 140mm is almost without advantage.
Knowable to above simulation result, using relative dielectric constant is 6.4, and dielectric loss is 0.002, length L, width When W, thickness T are respectively the dielectric base body 2 of 80mm, 10mm, 30mm, from gain, F/B ratio, frequency band angle for, preferably will Within the length of the 2nd electrode 4 is set in 108mm~130mm (state of (b)~(d) of Figure 12).
Other structure, effect, effect are identical with described 1st embodiment, therefore omit its narration.
(embodiment 3)
Figure 14 is the schematic isometric of the patch antenna device of the 3rd embodiment representing this invention, and Figure 15 is paster antenna The expanded view of element, Figure 16 is the constructed profile of the patch antenna element as power supply component, and Figure 17 is as unpowered unit The schematic isometric of the patch antenna element of part.
As shown in figure 14, the patch antenna device 200 of this embodiment has a pair paster arranged in parallel for D at regular intervals Antenna element 1A, 1B.
In this embodiment, the patch antenna device 1 of described 1st embodiment is employed as a pair patch antenna element. Therefore, understand for convenience, employ additional " A " in the patch antenna element itself as power supply component in its composition part Labelling, as the labelling employing additional " B " in the patch antenna element of unpowered element itself and its composition part.Separately Outward, it also is able to completely as patch antenna element 1A, 1B use the patch antenna device shown in Figure 11 and Figure 12.
That is, patch antenna element 1A (1B) is formed as electrode 3A, 4A (3B, 4B) are separately positioned on rectangular-shaped electricity Jie On the relative front 2Aa (2Ba) and back side 2Ab (2Bb) of matter matrix 2A (2B).
And, as shown in figure 15, dielectric base body 2A (2B) has front 2Aa (2Ba), back side 2Ab (2Bb), side 2Ac (2Bc) with 2Ad (2Bd), end face 2Ae (2Be) and 2Af (2Bf), electrode 3A, 4A (3B, 4B) are almost at front 2Aa (2Ba), the back of the body Whole of face 2Ab (2Bb) is upper to be formed.
As shown in figure 14, antenna assembly 200 is configured to: according to the electrode 4A of back side 2Ab and the patch of patch antenna element 1A The mode relative for electrode 3B of the front 2Ba of chip antenna element 1B, by interval D patch antenna element 1A, 1B arranged in parallel.
As in patch antenna element 1A of power supply component, it is connected to the coaxial cable 120 drawn from power supply section 100.
Specifically, as shown in figure 16, hole 2Ag, 4Aa of the electrode 3A of near patch antenna element 1A is opened in electrolyte base On body 2A and electrode 4A, and the inner conductor 121 of coaxial cable 120 is inserted in this some holes 2Ag, 4Aa so that it is be connected to electricity On the 3A of pole.It addition, the external conductor 122 of coaxial cable 120 is connected on electrode 4A.
In patch antenna element 1B as unpowered element, between the electrode of front and back side, it is connected to reactance Circuit 5.
Specifically, as shown in figure 17, hole 2Bg, 4Ba of the electrode 3B of near patch antenna element 1B is opened in electrolyte base On body 2B and electrode 4B, and wire is inserted in this some holes 2Bg, 4Ba so that it is one end is connected on electrode 3B, and will be another Outer one end is connected on the input of reactance circuit 5.And, the outfan of reactance circuit 5 is connected on wire 113, and On the electrode 4B of the rear side that this wire 113 is connected to ground connection.
As shown in FIG. 14 and 15, such patch antenna element 1A, 1B are identical shapes, set each electrode 3A, 3B The width W of (4A, 4B) is shorter than length L.That is, by patch antenna element 1A, 1B are simultaneously formed as elongated corner prism-shaped, Make, compared with general positive corner prism elements, to seek the miniaturization about width.
It addition, in this embodiment, patch antenna element 1B as unpowered element is distributed first with as power supply On the position of the reverse direction side that the radiation direction of patch antenna element 1A of part is corresponding.
Specifically, the radiation direction of electric wave is set in the electrode 3A side of patch antenna element 1A by antenna assembly 200, for Improve the gain of the electric wave arriving the direction, patch antenna element 1B is arranged in the radiation of the electric wave of patch antenna element 1A On the reverse direction side in direction, i.e. on the right side of Figure 14 only from the position of patch antenna element 1A interval D.
And, the interval D of patch antenna element 1A, 1B is set as the free space wavelength of the use frequency of UHF frequency band More than 0.12 times less than 0.30 times.
Below, antenna assembly 200 role and the effect of this embodiment will be illustrated.
Figure 18 is for antenna assembly 200 role of this embodiment and the diagrammatic side view of effect are described.
As shown in figure 18, the signal of assigned frequency is provided through coaxial cable 120 to patch antenna element 1A from power supply section 100 Time, encourage patch antenna element 1A, as shown by the solid line, from electrode 3A, 4A of patch antenna element 1A to patch antenna element 1A The electric wave V2 of face side and rear side radiation assigned frequency.
Then, after the electric wave V2 of electrode 4A side radiation with patch antenna element 1B electromagnetic coupled, patch antenna element 1B produces resonance under this assigned frequency, shown in dotted line, from electrode 3B, 4B to the face side of patch antenna element 1B and the back side Side radiation electric wave V3.By suitably setting reactance value and patch antenna element 1A, the 1B of the reactance circuit 5 of patch antenna element 1B Element spacing D, just can adjust phase place and the amplitude of this electric wave V3.
Therefore, by suitably adjusting phase place and the amplitude of the electric wave V3 of patch antenna element 1B, make towards paster antenna unit The electric wave V3 of the rear side of part 1B produces interference with the electric wave V2 from patch antenna element 1A, thus can be pressed down System.And, by making the electric wave V3 of the face side towards patch antenna element 1B and the front emitting to patch antenna element 1A The electric wave V2 of side produces interference, thus can be strengthened.
Therefore, it is possible to improve the gain of the electric wave of the frontal (left direction of Figure 18) of antenna assembly 200, and also The F/B of gain and the ratio of the gain of the electric wave in direction, the back side of the electric wave of frontal as antenna assembly 200 can be increased Ratio.
Inventor, in order to confirm this effect, has carried out following experiment.
Figure 19 is the relevant figure between element spacing D and gain, and Figure 20 is the relevant figure between element spacing D and F/B ratio.
In this experiment, constitute dielectric base body 2A, the relative dielectric constant of 2B be 6.4, width W, length L, thickness T For patch antenna element 1A, the 1B of 15mm, 80mm, 15mm, and the frequency is provided to be from power supply section 100 to patch antenna element 1A The signal of 920MHz.Then, change patch antenna element 1A, the element spacing D of 1B, analyze the gain under each element spacing D With F/B ratio, obtain the result shown in curve S4 as illustrated in figures 19 and 20.
It addition, the element spacing D in this experiment is expressed as using the multiple of the wavelength of frequency 920MHz.
Obviously, as shown in the curve S4 of Figure 19, in this antenna assembly 200, by setting element spacing D as wavelength 0.12 times~0.30 times, it is thus identified that the gain of about more than 5dB can be obtained.
It addition, as shown in the curve S4 of Figure 20, by setting element spacing D as 0.12 times~0.30 times of wavelength, also can Access the F/B ratio of about more than 7.5dB.
Then, dielectric base body 2A, the relative dielectric constant of 2B are changed, thus miniaturization patch antenna element 1A, 1B.
Specifically, set dielectric base body 2A, 2B relative dielectric constant as 21, and set patch antenna element 1A, After the width W of 1B, length L, thickness T are 10mm, 55mm, 15mm, carry out and described identical experiment, such as the curve S5 of Figure 19 Shown in, in the range of 0.12 times that element spacing D is wavelength~0.30 times, it is possible to while obtaining the gain of about more than 4dB, As shown in the curve S5 of Figure 20, it is possible to obtain the F/B ratio of about more than 6dB.
Further, the relative dielectric constant of dielectric base body 2A, 2B is brought up to 38, and sets patch antenna element 1A, 1B Width W, after length L, thickness T be 10mm, 40mm, 15mm, carry out and described identical experiment, such as the curve S6 institute of Figure 19 Show, in the range of 0.12 times that element spacing D is wavelength~0.30 times, it is possible to while obtaining the gain of about more than 3dB, as Shown in the curve S6 of Figure 20, it is possible to obtain the F/B ratio of about more than 5dB.
That is, for the antenna assembly 200 of this embodiment, it is thus identified that following facts: by by patch antenna element 1A, 1B Element spacing D is set in the range of 0.12 times~0.30 times of the wavelength using frequency, even if using surpassing of a length of 40mm Small-sized patch antenna element 1A, 1B, also can obtain the gain of about more than 3dB and the F/B ratio of about more than 5dB.
Afterwards, element spacing D is changed in 0.15 times of wavelength~the scope of 0.24 times by inventor, and confirms paster Between relation and reactance value and F/B ratio between reactance value and the gain of antenna assembly 200 of the reactance circuit 5 of antenna element 1B Relation.
Figure 21 is the relevant figure between reactance value, element spacing D and gain, and Figure 22 is reactance value, element spacing and F/B ratio Between relevant figure.
In this experiment, constitute dielectric base body 2A, the relative dielectric constant of 2B be 6.4, width W, length L, thickness T For patch antenna element 1A, the 1B of 15mm, 80mm, 15mm, and the frequency is provided to be from power supply section 100 to patch antenna element 1A The signal of 920MHz.Then, change the reactance value of the reactance circuit 5 of patch antenna element 1B, and analyze in each element spacing D Gain and F/B ratio.
So, the result as shown in curved surface Sg, Sfb of Figure 21 and Figure 22 has been obtained.
Obviously, as shown in the curved surface Sg of Figure 21, when the reactance value of setting reactance circuit 5 is about the value of j1.0 about Ω, energy Access the gain of more than 6dB.Generally, when using the single patch antenna element of same size, relative to 3~about 4dB Boundary, in the antenna assembly 200 of this embodiment, just can be improved the gain of 2~about 3dB by same size.
It addition, as shown in the curved surface Sfb of Figure 22, it is clear that it is about j1.0 about Ω at the reactance value setting reactance circuit 5 During value, it is possible to obtain the F/B ratio of more than 10dB.And, by the reactance value of reactance circuit 5 is set as with element spacing D Good value, it is possible to obtain the F/B ratio of more than 20dB.
As described previously for the antenna assembly 200 of this embodiment, miniaturization can be realized, also can obtain to frontal High-gain and big F/B ratio.
Further, since utilize patch antenna element 1A, 1B as element, therefore and between the unbalanced circuit such as coaxial line Coupling become easier to, and more effectively can provide signal from power supply section 100 to antenna assembly 200.
It is additionally, since patch antenna element 1B in patch antenna element 1A, 1B as the non-actuated element of unpowered, Therefore with using patch antenna element 1A, 1B compared with the antenna of exciting element, it is not necessary to signal distribution circuit etc., and knot Structure becomes simple, and the cost of antenna assembly 200 self can be made to become cheap.
Other structure, effect, effect are identical with described 1st and the 2nd embodiment, therefore omit its narration.
(embodiment 4)
Figure 23 is the schematic diagram of the structure of the antenna assembly of the 4th embodiment representing this invention, and Figure 24 is to represent each submatrix The axonometric chart of column unit structure, Figure 25 is the constructed profile of the 1st patch antenna element.
As shown in figure 23, the antenna assembly 201 of this embodiment has: n the integer of more than 2 (n be) sub-array units 210-1~210-n, and for arranging phase contrast rear to sub-array units 210-1 of regulation on the power of power supply section ~the allotter 6 of 210-n output.
As shown in figure 24, each sub-array units 210-1 (210-2~210-n) is by the power supply component as anterior locations 1st patch antenna element 1A and the 2nd patch antenna element 1B as the unpowered element of back location are constituted.That is, real at this Execute in example, by a pair patch antenna element 1A used in described 3rd embodiment, 1B as constituting each sub-array units 1st patch antenna element 1A of 210-1 (210-2~210-n) and the 2nd patch antenna element 1B.
1st patch antenna element 1A is made up of dielectric base body 2A, the 1st electrode 3A, the 2nd electrode 4A, and the 1st electrode 3A, 2nd electrode 4A be respectively formed at rectangular-shaped dielectric base body 2A relative before on 2Aa and 2Ab below.
And, as shown in Figure 23 and Figure 25, in each 1st patch antenna element 1A, connection has from the allocated device of power supply section 100 6 The coaxial cable 120 drawn.
As shown in figure 24, as unpowered element the 2nd patch antenna element 1B by dielectric base body 2B, the 1st electrode 3B, 2nd electrode 4B constitute, and the 1st electrode 3B, the 2nd electrode 4B be respectively formed at rectangular-shaped dielectric base body 2B relative before On face 2Ba and below 2Bb.
And, reactance circuit 5 is connected to the 2Bd side, side of the 2nd patch antenna element 1B.Therefore, it is configured to pass through reactance Circuit 5 just can adjust the reactance value that the 2nd patch antenna element 1B is overall.
Figure 26 is the side view of the 2nd patch antenna element 1B.
Multiple circuit can be applied as reactance circuit 5.Such as, single inductance or single electric capacity, inductance and electricity can be applied Series resonant circuit between appearance or antiresonant circuit, or series inductance or the circuit of electric capacity on these resonance circuits, Also has the circuit etc. replacing electric capacity to use the volume-variable elements such as varactor.
In this embodiment, application inductance is as reactance circuit 5.
Specifically, as shown in figure 26, the side 2Bd of dielectric base body 2B forms the 2nd patch antenna element 1B The lead division 51,52 of the 1st and the 2nd electrode 3B, 4B, and the two ends of inductance component 5 are connected on lead division 51,52.It addition, it is electric Sense is not limited only to the inductance component of chip part shape, also can be formed by electrode.Such as, as shown in figure 27, in dielectric base body 2B Side 2Bd on pattern form bending (meander) shape and the electrode 5 ' of suitable length, also the two ends of this electrode can be connected to On 1st and the 2nd electrode 3B, 4B.Therefore, it is possible to seek the reduction of component count.
As shown in figure 23 and figure 24, in the 1st and the 2nd patch antenna element 1A, 1B of such same shape, according to The mode that 1 patch antenna element 1A is positioned at before the 2nd patch antenna element 1B arranges.Specifically, the 1st and the 2nd paster antenna Element 1A, 1B are arranged in parallel by interval D, and the 2nd electrode 4A of the 1st patch antenna element 1A of anterior locations is facing to the 2nd paster The 1st electrode 3B of antenna element 1B.
Figure 28 is for the diagrammatic side view that the electric wave of each sub-array units 210-1 (210-2~210-n) radiates is described.
As shown in figure 23, from power supply section 100 by allotter 6 and coaxial cable 120 to each sub-array units 210-1 When 1st patch antenna element 1A of (210-2~210-n) provides power W1 (W2~Wn) of assigned frequency, such as the solid line of Figure 28 Shown in, forwards radiate the electric wave V2 of assigned frequency with rear from the 1st electrode 3A of the 1st patch antenna element 1A.
And, from electric wave V2 and the 2nd patch antenna element 1B of the 2nd electrode 4A side radiation of the 1st patch antenna element 1A After electromagnetic coupled, the 2nd patch antenna element 1B produces resonance with this assigned frequency.Therefore, shown in dotted line, the 2nd paster sky Kind of thread elements 1B radiates electric wave V3 to the forward direction of the 2nd patch antenna element 1B with rear direction from the 1st and the 2nd electrode 3B, 4B. Now, by suitably being adjusted phase place or the amplitude of electric wave V3 by reactance circuit 5, the rear towards the 2nd patch antenna element 1B is made Electric wave V3 produce interference with the electric wave V2 from the 1st patch antenna element 1A, thus can be inhibited.And, logical Cross the electric wave in electric wave V3 and the front emitting to the 1st patch antenna element 1A making the front towards the 2nd patch antenna element 1B V2 produces overlap, thus can be strengthened.
That is, by utilizing each sub-array units 210-1 (210-2~210-n), as shown in two dot dot dash, can be to each son The high-gain of front (left direction of Figure 28) radiation synthesis electric wave V2, V3 of array element 210-1 (210-2~210-n) Electric wave U1 (U2~Un).
As shown in figure 23, n sub-array units 210-1~210-n is arranged in string by interval D 1, and according to previous height 2nd electrode 4B of the 2nd patch antenna element 1B of array element 210-m (1≤m < n) faces toward later sub-array units 210- (m+1) mode of the 1st electrode 3A of the 1st patch antenna element 1A arranges.That is, so that all of sub-array units 210-1~ The mode of the electric wave radiation direction of 210-n (left of Figure 23) forward sets.
And, previous and later sub-array units 210-m, 210-(m+1) interval D 1 is set as using frequency About 1/2nd of free space wavelength.Specifically, interval D 1 is set as the frequency of the power W0 from power supply section 100 offer / 2nd of wavelength.
Allotter 6 is allotter known to one, is a kind of at Additional provisions on the power W0 that power supply section 100 provides Phase contrast, and the equipment of power W1~Wn of dislocation phase place it is respectively allocated to sub-array units 210-1~210-n.
Specifically, allotter 6 plays the role that and makes to previous and later sub-array units 210-m, 210-(m + 1) phase contrast of power Wm, Wm+1 of providing becomes 180 °.And, allotter 6 plays the role that backward submatrix The power Wm+1 that column unit 210-(m+1) provides is than Wm the advanced phase of power provided to previous sub-array element 210-m Differ from 180 °.
Therefore, the phase place of the electric wave radiated from later sub-array units 210-(m+1) is become than previous submatrix list The phase place of the electric wave of unit's 210-m radiation only shifts to an earlier date 180 °.
Below, antenna assembly role and the effect of this embodiment will be illustrated.
Figure 29 is the schematic diagram for antenna assembly role and effect are described.
As shown in figure 29, power W0, when power supply section 100 exports, by allotter 6, forms the merit with 180 ° of phase contrasts Rate W1~Wn, these power W1~Wn is respectively supplied to the 1st patch antenna element 1A of sub-array units 210-1~210-n.
Therefore, the electric wave Un, electric wave Un-1 that radiate as shown in two dot dot dash from last sub-array units 210-n exist Ratio, under the state that electric wave Un only postpones 180 ° of phase places, is radiated from previous sub-array element 210-(n-1).Then, such as dot-dash Electric wave U2 shown in line, when only postponing 180 ° × (n-2) phase place than electric wave Un, is put from sub-array units 210-2 Penetrating, finally, electric wave U1 as shown by the solid line is when only postponing 180 ° × (n-1) phase place than electric wave Un, from submatrix list Unit 210-1 is radiated.
Now, the interval D 1 of sub-array units 210-m, the 210-(m+1) owing to will abut against is set as from sub-array units / 2nd of the wavelength of the electric wave U1 (U2~Un) that 210-1 (210-2~210-n) radiates, therefore, emit to sub-array units All of electric wave U1~Un in the front of 210-1 becomes consistent.Its result, overlapping electric wave U1~Un, and put from antenna assembly 201 The gain of the electric wave penetrated is understood corresponding sub-array units number n and is uprised.
Inventor, in order to confirm this effect, has carried out following emulation.
Figure 30 is the relevant figure between the parts number of patch antenna element and gain.
In the simulation, constitute dielectric base body 2A, the relative dielectric constant of 2B be 6.4, width W, length L, thickness T (with reference to Figure 24) is the patch antenna element of 15mm, 80mm, 15mm, and provides frequency to be the merit of 920MHz to patch antenna element Rate.Then, change the parts number of patch antenna element, analyze the gain under each parts number, obtained as shown in figure 30 Result.
It addition, in the simulation, parts number is that gain time " 1 " represents that only emulation is with as the of unpowered element Gain during 1 patch antenna element 1A of 2 patch antenna element 1B, it is each that parts number is that gain time " 2 " represents that emulation is constituted Gain when the 1st and the 2nd patch antenna element 1A of sub-array units, 1B, parts number is that gain time " 4 " represents will be by the 1st Gain when forming a line with two sub-array units of the 2nd patch antenna element 1A, 1B composition and emulate, parts number is " 8 " Time gain represent gain when being formed a line by 4 sub-array units and emulate.
Obviously, as shown in figure 30, when the parts number of patch antenna element increases to twice, gain also increases about 3dBi.
Therefore, as shown in the antenna assembly 201 of this embodiment, by utilizing n sub-array units 210-1~210-n, really The several n according to sub-array units that accept can increase its gain.
As described previously for the antenna assembly 201 of this embodiment, due to the quantity according to sub-array units or paster antenna The quantity of element can increase the gain of electric wave, therefore, it is possible to realize the antenna assembly of radiation high-gain electric wave.
It is additionally, since the radiation direction being configured to along electric wave the 1st and the 2nd patch antenna element 1A, 1B to be formed a line Structure, therefore, it is possible to realize inhibiting the small-sized antenna assembly 201 of surface direction broadening.Its result, though respective antenna The electronic equipment that erection space is narrow, also can install the antenna assembly 201 of this embodiment easily.
Further, since using patch antenna element 1A, 1B as constitutive requirements, therefore with the unbalanced circuits such as coaxial line it Between coupling become easier to, and can more effectively power to antenna assembly 201 from power supply section 100.
Other structure, effect, effect are identical with described 1st to the 3rd embodiment, therefore omit its narration.
(embodiment 5)
Figure 31 is the schematic isometric of the antenna assembly of the 5th embodiment representing this invention, and Figure 32 is each paster antenna unit The constructed profile of part.
As shown in figure 31, the antenna assembly 202 of this embodiment has a pair paster antenna arranged in parallel for D at predetermined intervals Element 1A, 1A '.
Patch antenna element 1A (1A ') is the patch antenna device 1 of described 1st embodiment, is a kind of by electrode 3A, 4A (3A ', 4A ') is separately positioned on relative front 2Aa (2Aa ') and the back side 2Ab of rectangular-shaped dielectric base body 2A (2A ') The power supply component that (2Ab ') is upper and is formed.
As shown in figure 31, antenna assembly 202 is configured to: with electrode 4A and the paster of the back side 2Ab of patch antenna element 1A The mode relative for electrode 3A ' of the front 2Aa ' of antenna element 1A ', by interval D patch antenna element 1A arranged in parallel, 1A ', and It is connected to the coaxial cable 120,120 ' of patch antenna element 1A, 1A ' to power supply section 100 by allotter 6.
As shown in figure 32, each patch antenna element 1A (1A ') is connected to the coaxial cable 120 drawn from allotter 6 (120′)。
As shown in figure 31, such patch antenna element 1A, 1A ' they are identical shapes, it addition, each electrode 3A, 3A ' (4A, 4A ') width W be set to shorter than length L.That is, by patch antenna element 1A, 1A ' to be formed as elongated corner rib simultaneously Column so that compared with general square element, has sought the miniaturization about width.
Allotter 6 is that the power W0 of the assigned frequency in a kind of self-powered in future portion 100 is distributed into power W1, W2, and to patch The equipment of chip antenna element 1A, 1A ' power supply.
This allotter 6 has following functions: when distribution, arrange phase place in the phase place of power W1 with the phase place of power W2 After the recovery exports.In this embodiment, the phase contrast of power W1, W2 is set in more than 60 degree less than 120 degree.It addition, allotter During the function exported after not setting phase contrast, by changing the length of the coaxial cable 120 and 120 ' to each element, also can set Put described phase contrast.
It addition, as allotter 6, in addition to the allotter of the distribution ratio between equivalent distribution power W1 and power W2, also The allotter that inequality is distributed can be selected, but in this embodiment, have selected following allotter 6, this allotter 6 according to from The amplitude ratio of the radiation electric wave of the side in patch antenna element 1A, 1A ' exceeds 2dB from the amplitude of the radiation electric wave of the opposing party Above and the mode of below 6dB carrys out the distribution ratio between setting power W1 and power W2.
Such allotter 6 is circuit known to one, such as, can apply 90 degree of hybrid couplers, T branch circuit, prolong The circuit of the suitably distribution ratio of setting outlet side such as circuit late.
Below, antenna assembly 202 role and the effect of this embodiment will be illustrated.
Figure 33 is for antenna assembly 202 role of this embodiment and the diagrammatic side view of effect are described.
As shown in figure 33, when the power W0 of assigned frequency is provided from power supply section 100, in allotter 6 distribution power W1, Power W2 is supplied to patch antenna element 1A, 1A ' through coaxial cable 120,120 '.
Therefore, patch antenna element 1A, 1A ' encourage simultaneously, as shown by the solid line, from the electrode of patch antenna element 1A 3A, 4A are while the face side of patch antenna element 1A with the electric wave V2 of rear side radiation assigned frequency, shown in dotted line, from Electrode 3A ', the 4A ' of patch antenna element 1A ' is to the electricity of the face side of patch antenna element 1A ' with rear side radiation assigned frequency Ripple V3.
Now, by suitably setting the phase contrast between electric wave V2, V3, the desired radiation side of antenna assembly 202 can be improved To gain or F/B ratio.It addition, by the amplitude ratio suitably setting electric wave V2, V3, can preferably improve the increasing of radiation direction Benefit.
Such as, using the frontal (left direction of Figure 33) of patch antenna element 1A as the radiation side of antenna assembly 202 Xiang Shi, selects the phase place being supplied to the power W1 of patch antenna element 1A than the power W2 being supplied to patch antenna element 1A ' Phase place only postpones the allotter 6 of 60 degree~120 degree.
Therefore, by amplifying the electricity of the face side towards patch antenna element 1A from the electric wave V3 of patch antenna element 1A ' Ripple V2, improves the gain of the frontal of antenna assembly 202.It addition, make the electric wave V3 of the rear side towards patch antenna element 1A ' Produce interference with the electric wave V2 of the rear side of patch antenna element 1A and be suppressed, increase the F/B ratio of antenna assembly 202.
It addition, this phase contrast is when improving the gain of frontal of antenna assembly 202 further, select that there is following point The allotter 6 of proportioning: make the amplitude ratio of electric wave V2 of patch antenna element 1A from the shaking of electric wave V3 of patch antenna element 1A ' Width is big.
On the contrary, using the direction, the back side (right direction of Figure 33) of patch antenna element 1A ' as the radiation side of antenna assembly 202 Xiang Shi, selects the phase place being supplied to the power W2 of patch antenna element 1A ' than the power W1 being supplied to patch antenna element 1A Phase place only postpones the allotter 6 of 60 degree~120 degree.Therefore, amplified towards paster by the electric wave V2 from patch antenna element 1A The electric wave V3 of the rear side of antenna element 1A ', improves the gain in the direction, the back side of antenna assembly 202.It addition, make towards paster antenna The electric wave V3 of the face side of the electric wave V2 and patch antenna element 1A ' of the face side of element 1A produces interference and is suppressed, and increases The F/B ratio of antenna assembly 202.
It addition, this phase contrast is when improving the gain in direction, the back side of antenna assembly 202 further, select that there is following point The allotter 6 of proportioning: make the amplitude ratio of electric wave V3 of patch antenna element 1A ' from the shaking of electric wave V2 of patch antenna element 1A Width is big.
It addition, in this embodiment, select to employ the allotter 6 with described distribution ratio or phase contrast, and if using The allotter that these distribution ratios, phase contrast are variable, then just can improve gain or F/B ratio without exchanging allotter 6, and can also appoint Meaning changes the directivity of antenna assembly 202.
Inventor, in order to confirm for playing effect as above and the optimal phase contrast of effect and amplitude ratio, is carried out Following emulation.
Figure 34 is the relevant figure between phase contrast, amplitude ratio and gain, and Figure 35 is between phase contrast, amplitude ratio and F/B ratio Relevant figure.
In the simulation, constitute dielectric base body 2A, the relative dielectric constant of 2A ' be 6.4, width W, length L, thickness T is patch antenna element 1A of 15mm, 80mm, 15mm, 1A ', and press 60mm element spacing D arrangement, and from power supply section 100 to Patch antenna element 1A, 1A ' provide frequency to be the power of 900MHz.Then, the power W2 institute with patch antenna element 1A ' is changed The phase contrast of the power W1 of corresponding patch antenna element 1A, and analyze the gain under each amplitude ratio and F/B ratio.
The results are shown on curved surface Sg, Sfb of Figure 34 and Figure 35.
Here, as shown in curved surface Sg, Sfb, when phase contrast is arranged the phase contrast in the range of about 60 degree~120 degree, can obtain Gain and F/B ratio to more than 6dB.Almost identical with the patch antenna element of the antenna assembly 202 generally using this embodiment The single patch antenna element of size time the gain 3~about 4dB that obtains compare, in the antenna assembly 202 of this embodiment Can obtain exceeding the gain of about 2dB by same size.
It addition, as shown in the curved surface Sg of Figure 34, in the range of described phase contrast, even if from patch antenna element 1A, 1A ' electric wave amplitude zero difference in the case of (" amplitude ratio 0dB " of Figure 34 and Figure 35), also can obtain the height of more than 5dB Gain.But, as shown in the curved surface Sfb of Figure 35, by the amplitude of the electric wave of patch antenna element 1A is set to ratio paster sky The amplitude of the electric wave of kind of thread elements 1A ' only exceeds 2dB~6dB, can not only improve the gain of the frontal of antenna assembly 202, also F/B ratio can be increased further.
For the antenna assembly 202 of this embodiment, miniaturization can not only be realized and also simultaneously can also Obtain to the high-gain of frontal and big F/B ratio.
Further, since use patch antenna element 1A, 1A ' as element, therefore with the unbalanced circuit such as coaxial line it Between coupling become easier to, and more effectively can provide power from power supply section 100 to antenna assembly 202.
Other structure, effect, effect are identical with described 1st to the 4th embodiment, therefore omit its narration.
(embodiment 6)
Below, the 6th embodiment of this invention will be illustrated.
Figure 36 is the schematic diagram of the antenna device arrangement of the 6th embodiment representing this invention, and Figure 37 is to represent antenna assembly The axonometric chart of structure.
As shown in figure 36, the antenna assembly 203 of this embodiment has: n the integer of more than 2 (n be) patch antenna element 1A-1~1A-n, and for arrange on the power of power supply section phase contrast rear of regulation to patch antenna element 1A-1~ The allotter 6 of 1A-n output.
Each patch antenna element 1A-1 (1A-2~1A-n) is power supply component, as shown in figure 37, and in described 4th embodiment 1st patch antenna element 1A of middle application has identical structure.That is, each patch antenna element 1A-1 (1A-2~1A-n) is by electricity Dielectric matrix 2A, the 1st electrode 3A, the 2nd electrode 4A constitute, and with the coaxial cable 120 drawn from power supply section 100 the allocated device 6 Connect.1st electrode 3A and the 2nd electrode 4A be respectively formed at rectangular-shaped dielectric base body 2A relative before 2Aa with after On the 2Ab of face.
As shown in Figure 36 and Figure 37, n patch antenna element 1A-1~1A-n form a line by interval D, and later patch Chip antenna element 1A-(m+1) is positioned at the behind of previous patch antenna element 1A-m (1≤m < n).
That is, the 2nd electrode 4A of previous patch antenna element 1A-m (1≤m < n) and later patch antenna element 1A- (m+1) the 1st electrode 3A arranges relatively, and is set as the wave transmission direction of all of patch antenna element 1A-1~1A-n The most forward (left of Figure 36).
And, previous and later patch antenna element 1A-m, the interval D of 1A-(m+1) are set as oneself of use frequency By about 1/4th of space wavelength.
Allotter 6 is allotter known to one, and this allotter 6 plays the role that and makes to paste with later to previous The phase difference variable of power Wm, Wm+1 that chip antenna element 1A-m, 1A-(m+1) provides is in 90 °.And, allotter 6 plays as follows Effect: the power Wm+1 provided to later patch antenna element 1A-(m+1) is carried than to previous patch antenna element 1A-m The phase contrast of the power Wm of confession only shifts to an earlier date 90 °.
Therefore, the phase place of the electric wave radiated from later patch antenna element 1A-(m+1) is than previous patch antenna element The phase place of the electric wave of 1A-m radiation only shifts to an earlier date 90 °.
Below, antenna assembly role and the effect of this embodiment will be illustrated.
Figure 38 is the schematic diagram for antenna assembly role and effect are described.
As shown in figure 38, when power supply section 100 output W0, by allotter 6, form the merit with 90 ° of phase contrasts Rate W1~Wn, be respectively supplied to patch antenna element 1A-1~1A-n by these power W1~Wn.
Therefore, the electric wave Un ', electric wave Un-as shown in two dot dot dash is radiated from last patch antenna element 1A-n The phase place of 1 ', when only postponing 90 ° than electric wave Un ', radiates electric wave Un-from previous patch antenna element 1A-(n-1) 1′.Then, electric wave U2 ' as indicated by chain dotted lines is when only postponing 90 ° × (n-2) phase place than electric wave Un ', from paster sky Kind of thread elements 1A-2 radiation electric wave U2 ', finally, electric wave U1 ' as shown by the solid line is only postponing 90 ° × (n-1) phase place than electric wave Un ' State under, from patch antenna element 1A-1 radiate electric wave U1 '.
Now, it is set as from patch antenna element due to the interval D of patch antenna element 1A-m that will abut against, 1A-(m+1) / 4th of the wavelength of the electric wave U1 '~Un ' of 1A-1~1A-n radiation, therefore, before emitting to patch antenna element 1A-1 The all of electric wave U1 '~Un ' of side becomes completely the same.Its result, the gain from the electric wave of antenna assembly 203 radiation can correspondence Patch antenna element number n and uprise.
Inventor, in order to confirm this effect, has carried out following emulation.
Figure 39 is the relevant figure between parts number to gain.
In the simulation, also emulation with described 4th embodiment similarly constitutes the relative dielectric of dielectric base body 2A Constant is 6.4, width W, length L, thickness T are the patch antenna element of 15mm, 80mm, 15mm, and carry to patch antenna element It is the power of 920MHz for frequency.Then, change the parts number of patch antenna element, analyze the gain under each parts number, Arrive result as shown in figure 39.
Obviously, result as shown in figure 39, in the antenna assembly 203 of this embodiment, also by using n paster antenna Element 1A-1~1A-n, thus confirm and the increase of the gain corresponding to patch antenna element number n.
Other structure, effect, effect are identical with described 4th embodiment, therefore omit its narration.
(embodiment 7)
Figure 40 is the schematic isometric of the antenna assembly of the 7th embodiment representing this invention, and Figure 41 is to represent each paster sky Kind of thread elements, the constructed profile of switching connection status between switch 6, power supply section 100.
As shown in figure 40, the antenna assembly 204 of this embodiment has: a pair paster sky arranged in parallel for D at regular intervals Kind of thread elements 1A, 1A ' and switching switch 6.
Specifically, antenna assembly 204 is configured to: with electrode 4A and the paster sky of the back side 2Ab of patch antenna element 1A The mode relative for electrode 4A ' of the back side 2Ab ' of kind of thread elements 1A ', by interval D patch antenna element 1A arranged in parallel, 1A ' and logical Cross switching and switch 6 coaxial cables 120,120 ' being connected to patch antenna element 1A, 1A ' to power supply section 100.
As shown in figure 40, these patch antenna element 1A, 1A ' they are identical shapes, it addition, each electrode 3A, 3A ' (4A, 4A ') width W be set to shorter than length L.That is, by patch antenna element 1A, 1A ' to be formed as elongated corner rib simultaneously Column so that compared with general square element, has sought the miniaturization about width.
As shown in figure 40, draw coaxial cable 120,120 ' respectively from such patch antenna element 1A, 1A ', and by this A little coaxial cables 120,120 ' are connected on power supply section 100 by switching switch 6.
On the other hand, as shown in figure 41, switching switch 6 has travelling contact 61 and a pair fixed contact 62,63.And, Travelling contact 61 is connected with the inner conductor 111 of the coaxial cable 110 drawn from power supply section 100, and fixed contact 62,63 is with coaxial The inner conductor 121,121 ' of cable 120,120 ' connects.
Therefore, as shown by the solid line, when making the travelling contact 61 of switching switch 6 contact with fixed contact 62, paster antenna unit Part 1A becomes power supply component, and patch antenna element 1A ' becomes unpowered element.On the contrary, shown in dotted line, make travelling contact 61 with When fixed contact 63 contacts, patch antenna element 1A becomes unpowered element, and patch antenna element 1A ' becomes power supply component.
Below, antenna assembly 204 role and the effect of this embodiment will be illustrated.
Figure 42 is for antenna assembly 204 role of this embodiment and the diagrammatic side view of effect, Figure 43 are described Being to represent patch antenna element 1A in left side as the diagrammatic side view of directivity during power supply component, Figure 44 is to represent the right side The patch antenna element 1A ' of side is as the diagrammatic side view of directivity during power supply component.
Shown in solid such as Figure 42, when the travelling contact 61 making switching switch 6 contacts with fixed contact 62 from When power supply section 100 provides the signal of assigned frequency, provide this signal by switching switch 6 to patch antenna element 1A.
Work accordingly, as power supply component patch antenna element 1A and encourage.Its result, from patch antenna element Electrode 3A, 4A of 1A radiates electric wave V2 as shown by the solid line to the face side of patch antenna element 1A with rear side.
On the other hand, in this condition, patch antenna element 1A ' works as unpowered element, and with from patch The electric wave V2 of chip antenna element 1A produces resonance.Its result, from electrode 3A ', the 4A ' of patch antenna element 1A ' to paster antenna The face side of element 1A ' radiates electric wave V3 as shown by dashed lines with rear side.
Now, if adjustment sets from the length of the coaxial cable 120 ' of patch antenna element 1A ' extraction includes coaxial electrical During the additional reactance value of the patch antenna element 1A ' of cable 120 ', patch antenna element 1A and patch antenna element 1A ' are in front side In (left direction of Figure 42), become synchronization and produce resonance, and the gain of the frontal of antenna assembly 204 can uprise.Separately Outward, the electric wave V3 towards the rear side (right side of Figure 42) of patch antenna element 1A ' is suppressed, and the F/B of antenna assembly 204 is than meeting Become big.
That is, patch antenna element 1A ' works as reflector, and improves the electric wave of the left direction of antenna assembly 204 Gain or F/B ratio.Its result, as shown in figure 43, the directivity inclined left direction of antenna assembly 204.
Further, as shown in the dotted line of Figure 42, switching switching switch 6 makes travelling contact 61 and the fixed contact of switching switch 6 During 63 contact, provide the signal from power supply section 100, and patch antenna element by switching switch 6 to patch antenna element 1A ' 1A ' works as power supply component row energization of going forward side by side.
Its result, radiates as shown by dashed lines electric wave V3 to its face side with rear side from patch antenna element 1A '.And And, in this condition, patch antenna element 1A works as unpowered element, and with from patch antenna element 1A's ' Electric wave V3 produces resonance, radiates electricity as shown by the solid line to face side with rear side from electrode 3A, 4A of patch antenna element 1A Ripple V2.
Now, in the same manner as described, adjust if adjusting the length from the coaxial cable 120 of patch antenna element 1A extraction During the additional reactance value of patch antenna element 1A, patch antenna element 1A becomes on patch antenna element 1A ' direction overleaf Synchronize and produce resonance, and the gain in the direction, the back side of antenna assembly 204 can uprise.It addition, suppression is towards patch antenna element 1A The electric wave V2 of face side.
That is, during switching switching switch 6, patch antenna element 1A works as reflector, and improves antenna assembly 204 The gain of electric wave of right direction or F/B ratio.Its result, as shown in figure 44, the directivity of antenna assembly 204 becomes right direction.
For the antenna assembly 204 of this embodiment, miniaturization can not only be realized, and in front High-gain and big F/B ratio can also be obtained on direction or direction, the back side, and its directivity can be switched easily.
Further, since use patch antenna element 1A, 1A ' as element, therefore with the unbalanced circuit such as coaxial line it Between coupling become easier to, and more effectively can provide signal from power supply section 100 to antenna assembly 204.
It addition, in the antenna assembly 204 of this embodiment, using electrode 3A (3A ') of patch antenna element 1A (1A ') as Antenna electrode, and using electrode 4A (4A ') as ground electrode, using electrode 3A (3A ') towards as the face side of radiation direction, general Electrode 4A (4A ') arranges towards rear side.
But, as described in this embodiment, when small-sized and electrode 3A, 4A (3A ', 4A ') are almost same size, it is difficult to bright Really difference which be ground electrode, which be antenna electrode.And, no matter using which as ground electrode and antenna electric Pole, antenna performance is all without there being the biggest difference.
Therefore, even having the antenna assembly of the arrangement of patch antenna element 1A as shown in figure 45,1A ', all can rise To the effect identical with the antenna assembly 204 of described embodiment and effect.That is, even if as shown in Figure 45 (a), by paster antenna unit Part 1A ' is towards the direction contrary with embodiment, or as shown in Figure 45 (b), by patch antenna element 1A towards contrary with embodiment Direction, also can play the characteristic that the antenna assembly 204 with embodiment is identical.
Other structure, effect, effect are identical with described 1st to the 6th embodiment, therefore omit its narration.
(embodiment 8)
Below, the 8th embodiment of this invention will be illustrated.
Figure 46 is the schematic isometric of the antenna assembly of the 8th embodiment representing this invention, and Figure 47 is to be denoted as without supplying The constructed profile of the patch antenna element of electric device.
As shown in figure 46, the antenna assembly 205 of this embodiment has three patch antenna element 1B-1,1A, 1B-2.
These patch antenna element 1B-1,1A, 1B-2 are by adjacent patch antenna element 1A, the electricity of 1B-1 (1B-2,1A) Pole 4A, 3B (4B, 3A) mode D at predetermined intervals relative to each other is arranged in parallel.
And, using middle patch antenna element 1A as the power supply component being connected with power supply section 100, and by the patch of both sides Chip antenna element 1B-1,1B-2 are as the unpowered element with variable reactance circuit 5.
Patch antenna element 1A is directly connected on power supply section 100 by coaxial cable 120.
Variable reactance circuit 5 is being connected respectively and conduct as on patch antenna element 1B-1 of unpowered element, 1B-2 Terminal.
Specifically, as shown in figure 47, hole 2Bg, 4Ba of the electrode 3B of each patch antenna element 1B-1 (1B-2) will be arrived It is opened on dielectric base body 2B and electrode 4B, and wire 140 is inserted in this hole 2Bg, 4Ba so that it is one end is connected to electrode On 3B, and other end is connected on the input of variable reactance circuit 5.And, by the outfan of variable reactance circuit 5 It is connected on wire 141, and this wire 141 is connected on electrode 4B.
Known to can using, all of variable reactance circuit is as variable reactance circuit 5, and in this embodiment, utilizes Varicap defines variable reactance circuit 5.Specifically, varactor 53 is connected in series with inductance 54, and While the cathode side of varactor 53 is connected with wire 140, one end of inductance 54 is connected on wire 141.
Therefore, it is applied to the size of the DC voltage Vcc of the cathode side of varactor 53 by change and changes transfiguration The capacitance of diode 53 such that it is able to adjust the reactance value of variable reactance circuit 5 entirety.
It addition, this variable reactance circuit 5 is also identical with known variable reactance circuit, reactance value can be from Irritability scope Change to capacitive range.
Below, antenna assembly 205 role and the effect of this embodiment will be illustrated.
Figure 48 is for antenna assembly 205 role of this embodiment and the diagrammatic side view of effect, Figure 49 are described It it is the diagrammatic side view of the directivity representing antenna assembly 205.
As shown in figure 48, the letter of assigned frequency is provided through coaxial cable 120 to patch antenna element 1A from power supply section 100 Number, and while the variable reactance circuit 5 of patch antenna element 1B-1 is adjusted to Irritability reactance value, by patch antenna element The variable reactance circuit 5 of 1B-2 is adjusted to condensive reactance value.
So, patch antenna element 1B-1 works as reflector, thus suppression is towards patch antenna element 1A The electric wave V2 of rear side (right direction of Figure 48), and amplify face side (left direction of Figure 48) towards patch antenna element 1A Electric wave V2.
This improves the gain of the electric wave of the frontal of antenna assembly 205, increase F/B ratio, and in such as Figure 49 Directivity shown in solid.
On the contrary, if while the variable reactance circuit 5 of patch antenna element 1B-1 is adjusted to condensive reactance value, will patch The variable reactance circuit 5 of chip antenna element 1B-2 is adjusted to Irritability reactance value, then patch antenna element 1B-2 is as reflector And work, antenna assembly 205 is expressed as the directivity as shown in the dotted line of Figure 49.
For the antenna assembly 205 of this embodiment, the most small-sized and can obtain to frontal simultaneously High-gain and big F/B ratio, and patch antenna element 1B-1 can also be passed through, the variable reactance circuit 5 of 1B-2 changes sky easily The directivity of line apparatus 205.
Other structure, effect, effect are identical with described 1st to the 7th embodiment, therefore omit its narration.
(embodiment 9)
Below, the 9th embodiment of this invention will be illustrated.
Figure 50 is the profile of the major part of the antenna assembly of the 9th embodiment representing this invention.
In described 8th embodiment, be made up of varactor 53 and inductance 54 patch antenna element 1B-1,1B-2 can Power transformation reactive circuit, illustrates the variable reactance circuit 5 that can change its reactance value continuously.
In contrast, in this embodiment, the variable reactance circuit 5 of discrete this reactance value of change of energy is applied ".
Specifically, as shown in figure 50, by the switching switch 55 multiple constant reactance circuit 56~59 different with reactance value Constitute variable reactance circuit 5 ".
Therefore, by switching switching switch 55, any one among constant reactance circuit 56~59 and paster are connected Antenna element 1B-1 (1B-2) such that it is able to change variable reactance circuit 5 " reactance value.
Other structure, effect, effect are identical with described 2nd embodiment, therefore omit its narration.
It addition, this invention is not limited to described embodiment, invention main scope in can have various deformation or Change.
It addition, as shown in Fig. 1 or Figure 11, in the described embodiment, illustrate corresponding to the front 2a in dielectric base body 2 Whole the upper electrode 3 formed, the total length of electrode 4 is set to the patch antenna device identical or longer with the 3rd electrode.But It is as shown in figure 51, front 2a to be formed the 1st short electrode 3 of the length L length than the front 2a of dielectric base body 2 and incites somebody to action The total length of the 2nd electrode 4 is set to that the patch antenna device more longer than the 1st electrode 3 is the most necessarily included in the model of this invention In enclosing.
It addition, illustrate in described 2nd embodiment electrode 4 longer than electrode 3 and by its both ends 41,42 to electrolyte base The patch antenna device that both ends of the surface 2e of body 2,2f bend and configure.But, also can be by the length of at least one in electrode 3,4 Be set to the length than the front 2e of dielectric base body 2, back side 2f long and by this electrode to both ends of the surface 2e, 2f bending and configure. Therefore, electrode 3 longer than electrode 4 and by its both ends bend after in both ends of the surface 2e, 2f of dielectric base body 2 configuration invention also It is included in the range of this invention.
It addition, as shown in Fig. 1 or Figure 14, illustrate in the described embodiment: form dielectric base body 2 on cuboid (2A, 2B), and in its front 2a (2Aa, 2Ba), the upper electrode 3,4 that formed of whole of back side 2b (2Ab, 2Bb), and paster antenna is filled Put (patch antenna element) and be integrally formed into rectangular-shaped.But, if the width of patch antenna device 1 (patch antenna element) W, length L, thickness T meet the condition of regulation, and its section shape is almost rectangular shape, then patch antenna device 1 (patch Chip antenna element) shape be arbitrary.It is therefoie, for example, shown in Figure 52, both ends of the surface 2e, 2f (2Ae, 2Af, 2Be, 2Bf) are curved The semicircular patch antenna device of bent one-tenth (patch antenna element), or as shown in Figure 53, in dielectric base body 2 (2A, 2B) There is the patch antenna device (patch antenna element) of space 2h in the portion of centre, be also included in the range of this invention.
In the described embodiment, as shown in Fig. 2, Figure 10, Figure 16, Figure 25, Figure 32, Figure 41, as to the patch of power supply component The electric power-feeding structure of chip antenna device 1 (patch antenna element 1A), have employed the coaxial cable 120 drawn from power supply section 100 Inner conductor 121 be inserted into the dielectric base body 2 (2A) of patch antenna element 1 (1A) or electrode 4 (4A) hole 2g, 4a (2Ag, In 4Aa), it is thus connected on electrode 3 (3A), and external conductor 122 is connected to the structure on electrode 4 (4A), but supply Electricity structure is not limited to that.
Such as, as shown in Figure 54, by coaxial cable 120 being connected to patch antenna device 1 (patch antenna element 1A) Side on, in dielectric base body 2 (2A) or electrode 4 (4A), not perforate also can be powered.That is, by dielectric base body 2 (2A) the upper lead division 33,43 forming electrode 3,4 (3A, 4A) of side 2d (2Ad), and by the inner conductor of coaxial cable 120 121 lead divisions 33 being connected to electrode 3 (3A), and external conductor 122 is connected to the lead division 34 of electrode 4 (4A), with regard to energy Power to patch antenna device 1 (patch antenna element 1A) from power supply section 100.
It addition, also coaxial cable 120 can not be utilized but utilize electromagnetic coupled to come from power supply section 100 to patch antenna device 1 (patch antenna element 1A) powers.
It addition, as described in the explanation of the 7th embodiment, small-sized and time electrode 3A, 4A (3B, 4B) are almost same size, Be difficult to clearly distinguish which be ground electrode, which be antenna electrode.And, no matter using which as ground electrode and Antenna electrode, antenna performance is all without there being the biggest difference.
Therefore, the antenna assembly of the arrangement with patch antenna element 1A, 1B as shown in fig. 55 also can play with described Effect that the antenna assembly of embodiment is identical and effect.That is, as shown in Figure 55 (a), even patch antenna element 1A is placed in With the most contrary towards, as shown in Figure 55 (b), patch antenna element 1B is placed in the most contrary towards, it addition, such as figure Shown in 55 (C), patch antenna element 1A, 1B both of which are placed in the most contrary towards, also can play and described embodiment The identical characteristic of antenna assembly.And, the antenna assembly with these arrangements is also included within the range of this invention.
It addition, in described 4th embodiment, as shown in figure 23, illustrate reactance circuit 5 and each sub-array units 210- The antenna assembly that 2nd patch antenna element 1B of 1 (210-2~210-n) connects.But, it is not meant to by reactance circuit 5 not The antenna assembly that sub-array units 210-1~210-n that be connected with the 2nd patch antenna element 1B is constituted this invention scope it Outward.

Claims (5)

1. an antenna assembly, it is characterised in that:
It is respectively provided with a pair paster antenna unit that electrode is formed on the most opposed parallel two face of dielectric base body Part is the most arranged in parallel is that the electrode of a patch antenna element is facing with the electrode of another patch antenna element Mode,
The interval of described patch antenna element be set as more than 0.12 times and 0.30 times of free space wavelength that uses frequency with Under,
Power and as power supply component to a patch antenna element, and using another patch antenna element as unpowered unit Part,
Utilize the pair of patch antenna element as sub-array units, be positioned at according to the power supply component of later sub-array units Multiple sub-array units are configured to one by the mode of the behind of the unpowered element of previous sub-array units at regular intervals Row,
One patch antenna element is as the 1st patch antenna element, and another patch antenna element described is as the 2nd Patch antenna element, and using an electrode in each patch antenna element as the 1st electrode, and using another electrode as 2 electrodes,
The 1st paster of the 2nd electrode and later sub-array units according to the 2nd patch antenna element of previous sub-array units The mode of the 1st electrode contraposition of antenna element, is arranged in string at regular intervals by the plurality of sub-array units.
Antenna assembly the most according to claim 1, it is characterised in that:
Patch antenna element as described unpowered element is arranged in and the patch antenna element as described power supply component The position of radiation direction opposite side.
Antenna assembly the most according to claim 1, it is characterised in that:
It is used as terminal as connecting reactance circuit in the patch antenna element of described unpowered element.
Antenna assembly the most according to claim 1, it is characterised in that:
Previous sub-array units is set as using the free space of frequency with the described predetermined distance of later sub-array units / 2nd of wavelength,
To the power supply of the 1st patch antenna element of later sub-array units and the 1st paster sky to previous sub-array units The power supply of kind of thread elements arranges the phase contrast of 180 °.
Antenna assembly the most according to claim 2, it is characterised in that:
It is connected to reactance circuit in 2nd patch antenna element of described each sub-array units.
CN201310061377.3A 2006-11-06 2007-08-22 Patch antenna device and antenna assembly Expired - Fee Related CN103199343B (en)

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EP2477274A3 (en) 2013-08-28
EP2088643A4 (en) 2011-10-26
WO2008056476A1 (en) 2008-05-15
EP2477274A2 (en) 2012-07-18
EP2088643A1 (en) 2009-08-12
JPWO2008056476A1 (en) 2010-02-25
CN103199343A (en) 2013-07-10
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CN101536253B (en) 2013-09-11
US20090224981A1 (en) 2009-09-10

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